Your search keyword '"Raster scanning"' showing total 6 results

1. Beam delivery characteristics of the Hitachi carbon ion scanning system at Osaka Heavy Ion Medical Accelerator in Kansai (HIMAK).

Author

Tsubouchi, Toshiro, Beltran, Chris J., Yagi, Masashi, Hamatani, Noriaki, Takashina, Masaaki, Shimizu, Shinichi, Kanai, Tatsuaki, and Furutani, Keith M.

Subjects

*HEAVY ion accelerators, *SCANNING systems, *IRRADIATION

Abstract

Background: Using the pencil beam raster scanning method employed at most carbon beam treatment facilities, spots can be moved without interrupting the beam, allowing for the delivery of a dose between spots (move dose). This technique is also known as Dose‐Driven‐Continuous‐Scanning (DDCS). To minimize its impact on HIMAK patient dosimetry, there's an upper limit to the move dose. Spots within a layer are grouped into sets, or "break points," allowing continuous irradiation. The beam is turned off when transitioning between sets or at the end of a treatment layer or spill. The control system beam‐off is accomplished by turning off the RF Knockout (RFKO) extraction and after a brief delay the High Speed Steering Magnet (HSST) redirects the beam transport away from isocenter to a beam dump. Purpose: The influence of the move dose and beam on/off control on the dose distribution and irradiation time was evaluated by measurements never before reported and modelled for Hitachi Carbon DDCS. Method: We conducted fixed‐point and scanning irradiation experiments at three different energies, both with and without breakpoints. For fixed‐point irradiation, we utilized a 2D array detector and an oscilloscope to measure beam intensity over time. The oscilloscope data enabled us to confirm beam‐off and beam‐on timing due to breakpoints, as well as the relative timing of the RFKO signal, HSST signal, and dose monitor (DM) signals. From these measurements, we analyzed and modelled the temporal characteristics of the beam intensity. We also developed a model for the spot shape and amplitude at isocenter occurring after the beam‐off signal which we called flap dose and its dependence on beam intensity. In the case of scanning irradiation, we measured move doses using the 2D array detector and compared these measurements with our model. Result: We observed that the most dominant time variation of the beam intensity was at 1 kHz and its harmonic frequencies. Our findings revealed that the derived beam intensity cannot reach the preset beam intensity when each spot belongs to different breakpoints. The beam‐off time due to breakpoints was approximately 100 ms, while the beam rise time and fall time (tdecay) were remarkably fast, about 10 ms and 0.2 ms, respectively. Moreover, we measured the time lag (tdelay) of approximately 0.2 ms between the RFKO and HSST signals. Since tdelay ≈ tdecay at HIMAK then the HSST is activated after the residual beam intensity, resulting in essentially zero flap dose at isocenter from the HSST. Our measurements of the move dose demonstrated excellent agreement with the modelled move dose. Conclusion: We conducted the first move dose measurement for a Hitachi Carbon synchrotron, and our findings, considering beam on/off control details, indicate that Hitachi's carbon synchrotron provides a stable beam at HIMAK. Our work suggests that measuring both move dose and flap dose should be part of the commissioning process and possibly using our model in the Treatment Planning System (TPS) for new facilities with treatment delivery control systems with higher beam intensities and faster beam‐off control. [ABSTRACT FROM AUTHOR]

Published

2024

2. Full‐section otolith microtexture imaged by local‐probe X‐ray diffraction.

Author

Cook, Phil K., Mocuta, Cristian, Dufour, Élise, Languille, Marie-Angélique, and Bertrand, Loïc

Subjects

*X-ray diffraction, *SYNCHROTRONS, *VERTEBRATES, *FISH stocking, *BIOMINERALIZATION

Abstract

An optimized synchrotron‐based X‐ray diffraction method is described for the direct and efficient measurement of crystallite phase and orientation at micrometre resolution across textured polycrystalline samples of millimetre size (high scale dynamics) within a reasonable time frame. The method is demonstrated by application to biomineral fish otoliths. Otoliths are calcium carbonate accretions formed in the inner ears of vertebrates. Fish otoliths are essential biological archives, providing information for individual age estimation, the study of population dynamics and fish stock management, as well as past environmental and climatic conditions from archaeological specimens. Here, X‐ray diffraction mapping is discussed as a means of describing the mineralogical structure and microtexture of otoliths. Texture maps could be generated with a few a priori hypotheses on the aragonitic system. Full‐section imaging allows quantitative intercomparison of crystal orientation coupled to microstructural description, across the zones of the otoliths that represent distinctive mineral organization. It reveals the extents of these regions and their internal textural structure. Characterization of structural and textural correlations across whole images is therefore proposed as a complementary approach to investigate and validate the local in‐depth nanometre‐scale study of biominerals. The estimation of crystallite size and orientational distribution points to diffracting domains intermediate in size between the otolith nanogranules and the crystalline units, in agreement with recently reported results. [ABSTRACT FROM AUTHOR]

Published

2018

3. Combined intensity-modulated radiotherapy plus raster-scanned carbon ion boost for advanced adenoid cystic carcinoma of the head and neck results in superior locoregional control and overall survival.

Author

Jensen, Alexandra D., Nikoghosyan, Anna V., Poulakis, Melanie, Höss, Angelika, Haberer, Thomas, Jäkel, Oliver, Münter, Marc W., Schulz‐Ertner, Daniela, Huber, Peter E., and Debus, Jürgen

Subjects

*HEAD & neck cancer treatment, *ADENOID cystic carcinoma, *INTENSITY modulated radiotherapy, *HEALTH outcome assessment, *STEREOTACTIC radiotherapy

Abstract

BACKGROUND Local control in patients with adenoid cystic carcinoma (ACC) of the head and neck remains a challenge because of the relative radioresistance of these tumors. This prospective carbon ion pilot project was designed to evaluate the efficacy and toxicity of intensity-modulated radiotherapy (IMRT) plus carbon ion (C12) boost (C12 therapy). The authors present the first analysis of long-term outcomes of raster-scanned C12 therapy compared with modern photon techniques. METHODS Patients with inoperable or subtotally resected ACC received C12 therapy within the pilot project. Whenever C12 was not available, patients were offered IMRT or fractionated stereotactic radiotherapy (FSRT). Patients received either C12 therapy at a C12 dose of 3 Gray equivalents (GyE) per fraction up to 18 GyE followed by 54 Gray (Gy) of IMRT or IMRT up to a median total dose of 66 Gy. Toxicity was evaluated according to version 3 of the Common Toxicity Terminology for Adverse Events. Locoregional control (LC), progression-free survival (PFS), and overall survival (OS) were analyzed using the Kaplan-Meier method. RESULTS Fifty-eight patients received C12 therapy, and 37 received photons (IMRT or FSRT). The median follow-up was 74 months in the C12 group and 63 months in the photon group. Overall, 90% of patients in the C12 group and 94% of those in the photon group had T4 tumors; and the most common disease sites were paranasal sinus, parotid with skull base invasion, and nasopharynx. LC, PFS, and OS at 5 years were significantly higher in the C12 group (59.6%, 48.4%, 76.5%, respectively) compared with the photon group (39.9%, 27%, and 58.7%, respectively). There was no significant difference between patients who had subtotally resected and inoperable ACC. CONCLUSIONS C12 therapy resulted in superior LC, PFS, and OS without a significant difference between patients with inoperable and partially resected ACC. Extensive and morbid resections in patients with advanced ACC may need to be reconsidered. The most common site of locoregional recurrence remains in field, and further C12 dose escalation should be evaluated. Cancer 2015;121:3001-3009. © 2015 American Cancer Society. [ABSTRACT FROM AUTHOR]

Published

2015

4. Raster-scanning serial protein crystallography using micro- and nano-focused synchrotron beams.

Author

Coquelle, Nicolas, Brewster, Aaron S., Kapp, Ulrike, Shilova, Anastasya, Weinhausen, Britta, Burghammer, Manfred, and Colletier, Jacques-Philippe

Subjects

*CRYSTALLOIDS (Botany), *CRYSTALLIZATION, *NANOTECHNOLOGY, *LYSOZYMES, *SILICON nitride

Abstract

High-resolution structural information was obtained from lysozyme microcrystals (20 µm in the largest dimension) using raster-scanning serial protein crystallography on micro- and nano-focused beamlines at the ESRF. Data were collected at room temperature (RT) from crystals sandwiched between two silicon nitride wafers, thereby preventing their drying, while limiting background scattering and sample consumption. In order to identify crystal hits, new multi-processing and GUI-driven Python-based pre-analysis software was developed, named NanoPeakCell, that was able to read data from a variety of crystallographic image formats. Further data processing was carried out using CrystFEL, and the resultant structures were refined to 1.7 Å resolution. The data demonstrate the feasibility of RT raster-scanning serial micro- and nano-protein crystallography at synchrotrons and validate it as an alternative approach for the collection of high-resolution structural data from micro-sized crystals. Advantages of the proposed approach are its thriftiness, its handling-free nature, the reduced amount of sample required, the adjustable hit rate, the high indexing rate and the minimization of background scattering. [ABSTRACT FROM AUTHOR]

Published

2015

5. Three-dimensional arbitrary trajectory scanning photoacoustic microscopy.

Author

Yeh, ChENghung, Soetikno, Brian, Hu, Song, Maslov, Konstantin I., and Wang, Lihong V.

Abstract

We have enhanced photoacoustic microscopy with three-dimensional arbitrary trajectory (3-DAT) scanning, which can rapidly image selected vessels over a large field of view (FOV) and maintain a high signal-to-noise ratio (SNR) despite the depth variation of the vessels. We showed that hemoglobin oxygen saturation (sO2) and blood flow can be measured simultaneously in a mouse ear in vivo at a frame rate 67 times greater than that of a traditional two-dimensional raster scan. We also observed sO2 dynamics in response to switching from systemic hypoxia to hyperoxia. [ABSTRACT FROM AUTHOR]

Published

2015

6. A technique for the fast raster-scanned motion of a small window for millimeter-wave image acquisition.

Author

Soto, Josée and Dávila, J. A.

Subjects

*MICROWAVES, *SHORTWAVE radio, *RADIO waves, *ELECTRIC waves, *ELECTROMAGNETIC waves, *IMAGING systems, *OPTOELECTRONIC devices

Abstract

Here, we propose a technique that utilizes a Nipkow disk and an integrating sphere for the fast acquisition of millimeter-wave images. This technique has the potential for quietly achieving video frame rates. A demonstration of the principle is made in the optical region. © 2002 Wiley Periodicals, Inc. Microwave Opt Technol Lett 32: 440–442, 2002. [ABSTRACT FROM AUTHOR]

Published

2002